Optical assembly and the method to make the same

ABSTRACT

The present invention discloses an optical assembly. The optical assembly comprises: a first optical film having a first surface; an adhesive disposed on the first surface of the first optical film, wherein the adhesive comprises a photo-curable portion and a thermally-curable portion; and a second optical film comprising a photo-curable material bonded to the photo-curable portion of the adhesive, wherein the photo-curable portion of the adhesive is being bonded to the photo-curable material of the second optical film when the photo-curable portion of the adhesive is being cured and the thermally-curable portion of the adhesive has been cured.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. provisional patentapplication No. 62/310,815, filed on Mar. 21, 2016, which is herebyincorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an optical assembly, and moreparticularly to an optical assembly combined by an adhesive.

2. Description of Related Art

FIG. 1A illustrates a schematic cross-sectional view of an adhesiveoptical assembly 10. The optical assembly 10 includes a bottom lightenhancement film 11 and a top light enhancement film 12 disposed overthe bottom light enhancement film 11. Conventionally, coat a liquidadhesive layer 13 on the bottom surface of the top light enhancementfilm 12, insert the prisms of the bottom light enhancement film 11 intothe liquid adhesive layer 13 by embossing and subsequently perform aheat treatment process or a UV illumination process on the liquidadhesive layer 13 so that the liquid adhesive layer 13 proceeds to acrosslink reaction to form a solid film to finish the adhesion betweenthe bottom light enhancement film 11 and the top light enhancement film12. It is advantageous that the adhesive layer 13 in the liquid stateguarantees that there is enough contact area between the liquid adhesivelayer 13 and the prisms of the bottom light enhancement film 11 toprovide the adhesive stability of the optical assembly 10. However,because the adhesive layer 13 is in the liquid phase before adhesion, itis easy to see obvious “wick phenomenon” (i.e. capillarity phenomenon)during adhesion so that it is not easy to control the contact areabetween the liquid adhesive layer 13 and the prisms of the bottom lightenhancement film 11 and further the optical property after adhesion getsworse. The larger the contact area during adhesion is, the worse theoptical gain (i.e. brightness) is.

There is also another way to finish adhesion. Coat a liquid adhesivelayer 13 on the bottom surface of the top light enhancement film 12,perform the illumination process or the heat treatment process to makethe liquid adhesive layer 13 proceed to a crosslink reaction to form asolid film, and then insert the prisms of the bottom light enhancementfilm 11 into the solid adhesive layer 13 by embossing to finish theadhesion between the bottom light enhancement film 11 and the top lightenhancement film 12. It is advantageous that the liquid adhesive layer13 after solidification do not have flowability so as to reduce “wickphenomenon”. However, because the liquid adhesive layer 13 is solidifiedfirst, most of the bonding between the prisms of the bottom lightenhancement film 11 and the solid adhesive layer 13 is physical bonding,not chemical bonding, and therefore the adhesion force between thebottom light enhancement film 11 and the top light enhancement film 12is usually weaker so that it is easy to have the peeling of the adhesionproduct in the subsequent trimming and assembling.

Accordingly, the present invention proposes an optical assembly and itsmanufacturing method to overcome the above-mentioned disadvantages.

SUMMARY OF THE INVENTION

The present invention provides an optical assembly and a method formanufacturing the optical assembly which can effectively control thecontact area of the adhesion to avoid wick phenomenon in the adhesionprocess and guarantee the enough adhesive strength of the opticalassembly.

In one embodiment, the present invention discloses an optical assemblycomprising: a first optical film having a first surface; an adhesivedisposed on the first surface of the first optical film, wherein theadhesive comprises a photo-curable portion and a thermally-curableportion; and a second optical film comprising a photo-curable materialbonded to the photo-curable portion of the adhesive, wherein thephoto-curable portion of the adhesive is being bonded to thephoto-curable material of the second optical film when the photo-curableportion of the adhesive is being cured and the thermally-curable portionof the adhesive has been cured.

In one embodiment, the present invention discloses a method of formingan optical assembly comprising: providing a first optical film having afirst surface; disposing an adhesive on the first surface of the firstoptical film, wherein the adhesive comprises a photo-curable portion anda thermally-curable portion; and providing a second optical filmcomprising a photo-curable material bonded to the photo-curable portionof the adhesive, wherein the photo-curable portion of the adhesive isbeing bonded to the photo-curable material of the second optical filmwhen the photo-curable portion of the adhesive is being cured and thethermally-curable portion of the adhesive has been cured.

In one embodiment, the present invention discloses an optical assemblycomprising: a first optical film having a first surface; an adhesivedisposed on the first surface of the first optical film, wherein theadhesive comprises a thermally-curable portion and a photo-curableportion; and a second optical film comprising a thermally-curablematerial bonded to the thermally-curable portion of the adhesive,wherein the thermally-curable portion of the adhesive is being bonded tothe thermally-curable material of the second optical film when thethermally-curable portion of the adhesive is being cured and thephoto-curable portion of the adhesive has been cured.

In one embodiment, the present invention discloses an optical assemblycomprising: a first optical film having a first surface; an adhesivedisposed on the first surface of the first optical film, wherein theadhesive comprises a first curable portion and a second curable portion;and a second optical film comprising a curable material bonded to thesecond curable portion of the adhesive, wherein the first curableportion of the adhesive is cured by a first process, and the secondcurable portion of the adhesive and the curable material of the secondoptical film are cured by a second process different from the firstprocess, wherein the second curable portion of the adhesive is beingbonded to the curable material of the second optical film when thesecond curable portion of the adhesive is being cured and the firstcurable portion of the adhesive has been cured.

The detailed technology and above preferred embodiments implemented forthe present invention are described in the following paragraphsaccompanying the appended drawings for people skilled in this field towell appreciate the features of the claimed invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and many of the accompanying advantages of thisinvention will become more readily appreciated as the same becomesbetter understood by reference to the following detailed descriptionwhen taken in conjunction with the accompanying drawings, wherein:

FIG. 1 illustrates a schematic cross-sectional view of an adhesiveoptical assembly;

FIG. 2 illustrates a schematic cross-sectional view of an opticalassembly in the present invention;

FIG. 3A illustrates a schematic cross-sectional view of a lightdirecting portion of a microstructure;

FIG. 3B illustrates a schematic cross-sectional view of a bondingportion of a microstructure;

FIG. 4 illustrates a schematic cross-sectional view of a light directingportion and a bonding portion of a microstructure in another embodiment;

FIG. 5 illustrates a schematic cross-sectional view of a light directingportion and a bonding portion of a microstructure in another embodiment;and

FIG. 6A to FIG. 6E illustrate actual cross-sectional views of wickphenomenon in Example 1, Example 2, Example 3, Comparative Example 1 andComparative Example 2.

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS

The detailed explanation of the present invention is described asfollowing. The described preferred embodiments are presented forpurposes of illustrations and description and they are not intended tolimit the scope of the present invention.

FIG. 2 illustrates a schematic cross-sectional view of an opticalassembly 100 in the present invention. The optical assembly 100comprises a first optical film 101, a second optical film 102 and anadhesive 103 between the first optical film 101 and the second opticalfilm 102. The first optical film 101 has a top surface 101A and a bottomsurface 101B. The adhesive 103 is disposed on the bottom surface 101B ofthe first optical film 101. The second optical film 102 has a topsurface 102A and a bottom surface 102B. The adhesive 103 comprises aphoto-curable portion and a thermally-curable portion. The secondoptical film 102 comprises a photo-curable material bonded to thephoto-curable portion of the adhesive 103, wherein the photo-curableportion of the adhesive 103 is being bonded to the photo-curablematerial of the second optical film 102 when the photo-curable portionof the adhesive 103 is being cured and the thermally-curable portion ofthe adhesive 103 has been cured.

In one embodiment, the second optical film 102 comprise a plurality ofmicrostructures 104 (e.g. prisms or microlens, preferably, eachmicrostructure 104 is a prism), and the microstructures 104 are made ofthe photo-curable material bonded to the photo-curable portion of theadhesive 103, wherein the photo-curable portion of the adhesive 103 isbeing bonded to the photo-curable material of the microstructures 104 ofthe second optical film 102 when the photo-curable portion of theadhesive 103 is being cured and the thermally-curable portion of theadhesive 103 has been cured. Preferably, if wick phenomenon (between theadhesive 103 disposed on the bottom surface 101B of the first opticalfilm 101 and the microstructures 104 of the second optical film 102)results from the combination of the photo-curable portion of theadhesive 103 and the photo-curable material of the microstructures 104of the second optical film 102, increasing the surface area (the areanot embedded in the adhesive 103) of the microstructures 104 of thesecond optical film 102, reducing the thickness of the adhesive 103 orany other suitable method can improve the optical gain (i.e. brightness)of the optical assembly 100.

The adhesive 103 can be made of a combination of a first material and asecond material different from the first material, wherein the firstmaterial has the photo-curable function group(s) to serve as thephoto-curable portion of the adhesive 103 and the second material hasthe thermal-curable function group(s) to serve as the thermally-curableportion of the adhesive 103. The adhesive 103 can be also made of asingle material having the photo-curable function group(s) and thethermal-curable function group(s) respectively serving as thephoto-curable portion of the adhesive 103 and the thermally-curableportion of the adhesive 103.

The specific manufacturing method is described as follows:

In the beginning, dispose the adhesive 103 on the bottom surface 101B ofthe first optical film 101; at the moment, the adhesive 103 is in theliquid state. If the second optical film 102 is being bonded to theadhesive 103 in the liquid state, the interface between the adhesive 103in the liquid state and the second optical film 102 is inclined to havewick phenomenon to reduce to the optical gain (i.e. brightness) of theoptical assembly 100. In order to solve the above problem, the presentinvention uses the the adhesive 103 comprising two curable portionscured by different processes to improve the adhesive force between theadhesive 103 and the second optical film 102 and the optical gain of theoptical assembly 100 at the same time.

The adhesive 103 comprises a photo-curable portion which can be cured byan illumination process and a thermally-curable portion which can becured by the heat treatment process; however, the present invention isnot limited to this case (e.g., the adhesive 103 comprises a firstcurable portion which can be cured by a first process and a secondcurable portion which can be cured by a second process). Afterperforming the heat treatment process on the adhesive 103 in the liquidphase on the bottom surface 101B of the first optical film 101, thethermally-curable portion of the adhesive 103 is cured but thephoto-curable portion of the adhesive 103 is not cured. Therefore, thephase of the adhesive 103 on the bottom surface 101B of the firstoptical film 101 is changed from the liquid phase to the semi-solidphase after the heat treatment process. Subsequently, bond the secondoptical film 102 to the adhesive 103 in the semi-solid phase on thebottom surface 101B of the first optical film 101. Because the adhesive103 in the semi-solid phase has less flowability than the adhesive 103in the liquid phase, wick phenomenon can be largely improved when thesecond optical film 102 is being bonded to the adhesive 103 in thesemi-solid state. When bonding the second optical film 102 to theadhesive 103 in the semi-solid phase on the bottom surface 101B of thefirst optical film 101, an illumination process is performed on thephoto-curable portion of the adhesive 103 (uncured) and thephoto-curable material of the second optical film 102 (at the moment,the photo-curable material of the second optical film 102 can be notcured or partially cured by controlling the UV illumination energy inthe illumination process to make the photo-curable material of thesecond optical film 102 only finish a portion of the crosslink-curingreaction) to completely finish the chemical bonding. Therefore, thephase of the adhesive 103 between the first optical film 101 and thesecond optical film 102 is changed from the semi-solid phase to thesolid phase and the phase of the photo-curable material of the secondoptical film 102 is changed to the solid phase after the illuminationprocess.

The advantages of the above manufacturing method comprise: (a) Byoptimizing the weight ratio of the photo-curable portion and thethermal-curable portion of the adhesive 103, the hardness of theadhesive 103 in the semi-solid state after the heat treatment processcan be adjusted to further control the insertion depth in the adhesive103 of the microstructures 104 of the second optical film 102;meanwhile, because the adhesive 103 in the semi-solid state does nothave flowability, wick phenomenon can be effectively improved. Beside,the contact area of the microstructures 104 of the second optical film102 in the adhesive process can be precisely controlled; (b) In theadhesive process, because the adhesive 103 in the semi-solid state andthe microstructures 104 of the second optical film 102 both have thenon-reactive photo-curable function group(s), photo-polymerization canbe performed to form chemical bonding in the subsequent UV illuminationto further provide enough adhesive force between the first optical film101 and the second optical film 102.

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 can be further configured to improve theadhesive force between the adhesive 103 and the microstructures 104 ofthe second optical film 102 and the optical gain of the optical assembly100 at the same time. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 100 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.6. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 120 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.62. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 140 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.62. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 160 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.65. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 180 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.65. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 200 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.67. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 220 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.67. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 250 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.7. In other words, the specific weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 can meet the adhesive force and the optical gain which areabove-mentioned.

The thickness of the adhesive 103 can be 0.5˜3 μm. The weight ratio ofthe photo-curable portion to the thermally-curable portion of theadhesive 103 and the thickness of the adhesive 103 can be furtherconfigured to improve the adhesive force between the adhesive 103 andthe microstructures 104 of the second optical film 102 and the opticalgain of the optical assembly 100 at the same time. In one embodiment,the thickness of the adhesive 103 can be 0.5˜2 μm. In one embodiment,the thickness of the adhesive 103 can be 0.5˜1.5 μm (1˜1.5 μm or 0.5˜1μm). Although the thickness of the adhesive 103 is smaller (e.g. <1.5μm), the adhesive force is large enough to avoid the separation of theadhesive 103 and the microstructures 104 of the second optical film 102.Besides, the smaller thickness of the adhesive 103 can improve theoptical gain. Preferably, if wick phenomenon (between the adhesive 103disposed on the bottom surface 101B of the first optical film 101 andthe microstructures 104 of the second optical film 102) results from thecombination of the photo-curable portion of the adhesive 103 and thephoto-curable material of the microstructures 104 of the second opticalfilm 102, increasing the surface area (the area not embedded in theadhesive 103) of the microstructures 104 of the second optical film 102,reducing the thickness of the adhesive 103 or any other suitable methodcan improve the optical gain of the optical assembly 100.

Each microstructure 104 has a light directing portion 104A and a bondingportion 104B bonded to the adhesive 103. FIG. 3A illustrates a schematiccross-sectional view of a light directing portion 104A of amicrostructure 104. FIG. 3B illustrates a schematic cross-sectional viewof a bonding portion 104B of a microstructure 104. The light directingportion 104A has two intersecting extending-facets (e.g.,extending-planes) 104X defining a first dihedral angle Θ₁ and thebonding portion 104B has two intersecting facets (e.g., planes) 104Ydefining a second dihedral angle Θ₂, wherein the first dihedral angle Θ₁is substantially equal to the second dihedral angle Θ₂ (in fact, the twointersecting extending-facets 104X of the light directing portion 104Ais consistent with the two intersecting facets 104Y of the bondingportion 104B). Preferably, the first dihedral angle Θ₁ (or the seconddihedral angle Θ₂) is 90 degrees; however, the present invention is notlimit to this case. The microstructure 104 can extend along a firstdirection; in one embodiment, the microstructure 104 can be a regularmicrostructure having a cross-sectional shape of the same size along afirst direction (e.g., regular prism or regular lens). Themicrostructure 104 can be a bulk microstructure (e.g., microlens).Specifically, the present invention adopts regular microstructures 104(regular triangular prism preferably) to be boned to the adhesive 103;the microstructure 104 does not need to have special shape to increasethe area contacting the adhesive 103 to increase adhesive force, so itcan reduce the process complexity. Moreover, the smaller thickness ofthe adhesive 103 is (e.g. <1.5 μm) and regular microstructures can alsoreduce the total thickness of the optical assembly 100.

FIG. 4A illustrates a schematic cross-sectional view of a lightdirecting portion 104A and a bonding portion 104B of a microstructure104 in another embodiment. The second dihedral angle Θ₂ can be smallerthan the first dihedral angle Θ₁ so that the bonding portion 104B hasmore area contacting the adhesive 103 to improve the adhesive force.Moreover, the bonding portion 104B can have two parallel facets (e.g.,planes) 104Z so that the bonding portion 104B has more area contactingthe adhesive 103 to improve the adhesive force (see FIG. 5).

The first optical film 101 can be any suitable optical film, such aslight enhancement film, diffusing sheet, DBEF and so on. The secondoptical film 102 can be also any suitable optical film, such as lightenhancement film, diffusing sheet, DBEF and so on. The first opticalfilm 101 may comprise a substrate 101S (e.g., PET substrate) and themicrostructure layer 101M disposed on the substrate 101S. The secondoptical film 102 may have a substrate 102S (e.g., PET substrate) and themicrostructure layer 102M disposed on the substrate 102S.

The present invention can also achieve the goal of providing sufficientadhesive force between the adhesive 103 and the microstructures 104 ofthe second optical film 102 while maintaining the optical gain of theoptical assembly 100 within operating ranges simply by selecting theappropriate weight ratio of the photo-curable portion to thethermally-curable portion of the adhesive 103 with respect to thephoto-curable material of the second optical film 102 without addingother complex processes, thereby the manufacturing cost can be largelyreduced.

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive is 0.11˜4. Decrease the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 so that there is more thermally-curable portion which has been curedin the adhesive 103 after the heat treatment process. In other words,there is less photo-curable portion having flowability in theillumination process for bonding between the first optical film and thesecond optical film so as to largely reduce wick phenomenon

The smaller weight ratio of the photo-curable portion to thethermally-curable portion of the adhesive 103 can contribute to theimprovement of wick phenomenon; however, because the less photo-curableportion of the adhesive 103 can be bonded to the second optical film forchemical bonding, the adhesion force between the adhesive 103 and themicrostructures 104 of the second optical film 102 is so weak that it ispossible that the separation of the adhesive 103 and the second opticalfilm 102 (or the microstructures 104 of the second optical film 102)often happens in the subsequent process; the larger weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 can worsen wick phenomenon and the optical gain of the opticalassembly 100 is largely reduced. Therefore, the optimal weight ratio ofthe photo-curable portion to the thermally-curable portion of theadhesive 103 can improve wick phenomenon and the adhesion force at thesame time

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 can be further configured to improve theadhesive force between the adhesive 103 and the microstructures 104 ofthe second optical film 102 and the optical gain of the optical assembly100 at the same time. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is 0.25˜2.33. In one embodiment, the weight ratio of thephoto-curable portion to the first thermally-curable portion of theadhesive 103 is 0.3˜1.08. Preferably, if wick phenomenon (between theadhesive 103 disposed on the bottom surface 101B of the first opticalfilm 101 and the microstructures 104 of the second optical film 102)results from the combination of the photo-curable portion of theadhesive 103 and the photo-curable material of the microstructures 104of the second optical film 102, increasing the surface area (the areanot embedded in the adhesive 103) of the microstructures 104 of thesecond optical film 102, reducing the thickness of the adhesive 103 orany other suitable method can improve the optical gain of the opticalassembly 100.

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 is 0.11˜4 such that the adhesive forcebetween the adhesive 103 and the microstructures 104 of the secondoptical film 102 is larger than 100 g/25 mm and the optical gain of theoptical assembly is larger than 1.6. The present invention uses theweight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 and the photo-curable material of themicrostructures 104 of the second optical film 102 to improve theadhesive force between the adhesive 103 and the microstructures 104 ofthe second optical film 102 and the optical gain of the optical assembly100 at the same time. Preferably, if wick phenomenon (between theadhesive 103 disposed on the bottom surface 101B of the first opticalfilm 101 and the microstructures 104 of the second optical film 102)results from the combination of the photo-curable portion of theadhesive 103 and the photo-curable material of the microstructures 104of the second optical film 102, increasing the surface area (the areanot embedded in the adhesive 103) of the microstructures 104 of thesecond optical film 102, reducing the thickness of the adhesive 103 orany other suitable method can improve the optical gain of the opticalassembly 100.

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 and the photo-curable material of themicrostructures 104 of the second optical film 102 can be furtherconfigured to improve the adhesive force between the adhesive 103 andthe microstructures 104 of the second optical film 102 and the opticalgain of the optical assembly 100 at the same time. In one embodiment,the weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 is configured such that the adhesive forcebetween the adhesive 103 and the microstructures 104 of the secondoptical film 102 is larger than 100 g/25 mm and the optical gain of theoptical assembly 100 is larger than 1.6. In one embodiment, the weightratio of the photo-curable portion to the thermally-curable portion ofthe adhesive 103 is configured such that the adhesive force between theadhesive 103 and the microstructures 104 of the second optical film 102is larger than 120 g/25 mm and the optical gain of the optical assembly100 is larger than 1.62. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 140 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.62. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 160 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.65. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 180 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.65. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 200 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.67. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 220 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.67. In one embodiment, the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 is configured such that the adhesive force between the adhesive 103and the microstructures 104 of the second optical film 102 is largerthan 250 g/25 mm and the optical gain of the optical assembly 100 islarger than 1.7. In other words, the specific weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive103 can meet the adhesive force and the optical gain which areabove-mentioned.

The thickness of the adhesive 103 can be 0.5˜3 μm. The weight ratio ofthe photo-curable portion to the thermally-curable portion of theadhesive 103 and the thickness of the adhesive 103 can be furtherconfigured to improve the adhesive force between the adhesive 103 andthe microstructures 104 of the second optical film 102 and the opticalgain of the optical assembly 100 at the same time. In one embodiment,the thickness of the adhesive 103 can be 0.5˜2 μm. In one embodiment,the thickness of the adhesive 103 can be 0.5˜1.5 μm (1˜1.5 μm or 0.5˜1μm). Although the thickness of the adhesive 103 is smaller (e.g. <1.5μm), the adhesive force is large enough to avoid the separation of theadhesive 103 and the microstructures 104 of the second optical film 102.Besides, the smaller thickness of the adhesive 103 can improve theoptical gain. Preferably, if wick phenomenon (between the adhesive 103disposed on the bottom surface 101B of the first optical film 101 andthe microstructures 104 of the second optical film 102) results from thecombination of the photo-curable portion of the adhesive 103 and thephoto-curable material of the microstructures 104 of the second opticalfilm 102, increasing the surface area (the area not embedded in theadhesive 103) of the microstructures 104 of the second optical film 102,reducing the thickness of the adhesive 103 or any other suitable methodcan improve the optical gain of the optical assembly 100.

EXPERIMENTS

The following examples take a test of “the weight ratio of thephoto-curable portion to the thermally-curable portion of the adhesive”vs “the photo-curable material of the prisms of the second opticalfilm”. However, the present invention is not limited to these examples.In these examples, the photo-curable material of the prisms 104 of thesecond optical film 102 are the same, the thermally-curable portion ofthe adhesive 103 is made of combination of EM-2000 (manufactured byNegami chemical industrial Company) and SN-50 (manufactured by Negamichemical industrial Company), and the photo-curable portion of theadhesive 103 is made of Bisphenol A (EO)₃₀ Dimethacrylate (M2301,manufactured by Miwon Company) and Isodecyl Acrylate (M130, manufacturedby Miwon Company). Moreover, photoinitiator 184 is added in eachexample. After four hours of stirring at normal temperature, proceed tocoating, preparing and manufacturing of sample and physical measurement.The measurement result is list in Table 1 and FIG. 6A to FIG. 6Eillustrate real cross-sectional views in Example 1, Example 2, Example3, Comparative Example 1 and Comparative Example 2.

TABLE 1 Compar- Compar- Exam- Exam- Exam- ative ative ple 1 ple 2 ple 3Example 1 Example 2 the weight ratio of 0 0.33 1 3 ∞ the photo-curableportion to the thermally-curable portion of the adhesive the thicknessof the 1~1.5 1~1.5 1~1.5 1~1.5 1~1.5 adhesive (μm) optical gain 1.671.66 1.64 1.60 1.55 (brightness) adhesive force 117 202 231 233 238(g/25 mm) wick phenomenon none none slight worse the worst

Example 1

The material of the adhesive 103 in Example 1 is all thermal-curable.Coat the adhesive 103 on the bottom surface 101B of the first opticalfilm 101 and heat the adhesive 103 to dry the solvent of the adhesive103 such that the adhesive 103 proceeds to a thermal-curable reaction.Because the adhesive 103 is in the solid state after the thermal-curablereaction, the adhesive 103 can not flow in the adhesive process so as tocompletely overcome wick phenomenon. Control the thickness of theadhesive 103 to 1˜1.5 μm, bond the prisms 104 of the second optical film102 to the adhesive 103 by embossing of the roll such that the adhesive103 and the prisms 104 of the second optical film 102 are physicallybonded. The optical gain is 1.67. Because the adhesive 103 is all madeof the thermal-curable material, the prisms 104 of the second opticalfilm 102 are bonded only by physical bonding (no chemical bonding).Therefore, the adhesive force is relative low, merely about 117 g/25 mm,as shown in Table 1.

Example 2

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 in Example 2 is 0.33. Coat the adhesive 103on the bottom surface 101B of the first optical film 101 and heat theadhesive 103 to dry the solvent of the adhesive 103 such that thethermal-curable portion of the adhesive 103 proceeds to athermal-curable reaction. Control the thickness of the adhesive 103 to1˜1.5 μm, bond the prisms 104 of the second optical film 102 to theadhesive 103 by embossing of the roll such that the adhesive 103 and theprisms 104 of the second optical film 102 are physically bonded. Becausethe weight ratio 0.67 of the thermal-curable portion to thephoto-curable portion of the adhesive 103 is larger, the adhesive 103 isdried to be in the semi-solid state and the adhesive 103 can not flow inthe adhesive process so as to completely overcome wick phenomenon.Moreover, the photo-curable portion of the adhesive 103 and the prisms104 of the second optical film 102 can proceed to a crosslink-curablereaction by UV illumination process to form chemical bonding. Therefore,the adhesive force can be improved to be 202 g/25 mm and the opticalgain is 1.66, as shown in Table 1.

Example 3

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 in Example 3 is 1. Coat the adhesive 103 onthe bottom surface 101B of the second optical film 102 and heat theadhesive 103 to dry the solvent of the adhesive 103 such that thethermal-curable portion of the adhesive 103 proceeds to athermal-curable reaction. Control the thickness of the adhesive 103 to1˜1.5 μm, bond the prisms 104 of the second optical film 102 to theadhesive 103 by embossing of the roll such that the adhesive 103 and theprisms 104 of the second optical film 102 are physically bonded. Becausethe adhesive 103 has the weight ratio 1 of the thermal-curable portionto the photo-curable portion, the adhesive 103 is dried to be still inthe semi-solid state and the adhesive 103 can not easily flow in theadhesive process so as to still completely overcome wick phenomenon.Moreover, the photo-curable portion of the adhesive 103 and the prisms104 of the second optical film 102 can proceed to a crosslink-curablereaction by UV illumination process to form chemical bonding. Therefore,the adhesive force can be improved to be 231 g/25 mm. However, slightwick phenomenon occurs so that the optical gain is relative low, 1.64,as shown in Table 1.

Comparative Example 1

The weight ratio of the photo-curable portion to the thermally-curableportion of the adhesive 103 in Comparative Example 1 is 3. Coat theadhesive 103 on the bottom surface 101B of the second optical film 102and heat the adhesive 103 to dry the solvent of the adhesive 103 suchthat the thermal-curable portion of the adhesive 103 proceeds to athermal-curable reaction. Control the thickness of the adhesive 103 to1˜1.5 μm, bond the prisms 104 of the second optical film 102 to theadhesive 103 by embossing of the roll such that the adhesive 103 and theprisms 104 of the second optical film 102 are physically bonded. Thephoto-curable portion of the adhesive 103 and the prisms 104 of thesecond optical film 102 can proceed to a crosslink-curable reaction byUV illumination process to form chemical bonding. Therefore, theadhesive force can be improved to be 233 g/25 mm. Because the adhesive103 only has the weight ratio 0.33 of the thermal-curable portion to thephoto-curable portion, the adhesive 103 still has flowability afterdrying and thermal curing so as to not completely overcome wickphenomenon. Therefore, the optical gain is relative low, 1.60, as shownin Table 1.

Comparative Example 2

The material of the adhesive 103 in Example 1 is all photo-curable. Coatthe adhesive 103 on the bottom surface 101B of the second optical film102 and heat the adhesive 103 to dry the solvent of the adhesive 103.Control the thickness of the adhesive 103 to 1˜1.5 μm, bond the prisms104 of the second optical film 102 to the adhesive 103 by embossing ofthe roll. The photo-curable material of the adhesive 103 and the prisms104 of the second optical film 102 can proceed to a crosslink-curablereaction by UV illumination process to form chemical bonding. Becausethe adhesive 103 is all made of the photo-curable material, the adhesive103 has flowability after drying and thermal curing and the worst wickphenomenon occurs. Therefore, although the adhesive force can beincreased to be 238 g/25 mm, the optical gain is relative lower, merelyabout 1.55, as shown in Table 1.

In one embodiment, the above manufacturing method can be correspondinglymodified to apply to the optical assembly comprising: a first opticalfilm having a first surface; an adhesive disposed on the first surfaceof the first optical film, wherein the adhesive comprises athermally-curable portion and a photo-curable portion; and a secondoptical film comprising a thermally-curable material bonded to thethermally-curable portion of the adhesive, wherein the thermally-curableportion of the adhesive is being bonded to the thermally-curablematerial of the second optical film when the thermally-curable portionof the adhesive is being cured and the photo-curable portion of theadhesive has been cured. Therefore, it does not be further describedherein.

The above disclosure is related to the detailed technical contents andinventive features thereof. People skilled in this field may proceedwith a variety of modifications and replacements based on thedisclosures and suggestions of the invention as described withoutdeparting from the characteristics thereof Nevertheless, although suchmodifications and replacements are not fully disclosed in the abovedescriptions, they have substantially been covered in the followingclaims as appended.

What is claimed is:
 1. An optical assembly, comprising: a first opticalfilm having a first surface; an adhesive disposed on the first surfaceof the first optical film, wherein the adhesive comprises aphoto-curable portion and a thermally-curable portion; and a secondoptical film comprising a photo-curable material bonded to thephoto-curable portion of the adhesive, wherein the photo-curable portionof the adhesive is being bonded to the photo-curable material of thesecond optical film when the photo-curable portion of the adhesive isbeing cured and the thermally-curable portion of the adhesive has beencured.
 2. The optical assembly according to claim 1, wherein the secondoptical film comprises a plurality of microstructures, wherein theplurality of microstructures are made of the photo-curable materialbonded to the photo-curable portion of the adhesive.
 3. The opticalassembly according to claim 1, wherein the photo-curable portion of theadhesive is cured by an illumination process, and the thermally-curableportion of the adhesive is cured by a heat treatment process.
 4. Theoptical assembly according to claim 1, wherein each of the plurality ofmicrostructures has a light directing portion and a bonding portionbonded to the adhesive, wherein the light directing portion has twointersecting extending-facets defining a first dihedral angle and thebonding portion has two intersecting facets defining a second dihedralangle, wherein the first dihedral angle is substantially equal to thesecond dihedral angle.
 5. The optical assembly according to claim 1,wherein each of the plurality of microstructures has a light directingportion and a bonding portion bonded to the adhesive, wherein the lightdirecting portion has two intersecting extending-planes defining a firstdihedral angle and the bonding portion has two intersecting planesdefining a second dihedral angle.
 6. The optical assembly according toclaim 5, wherein the second dihedral angle is substantially equal to thefirst dihedral angle.
 7. The optical assembly according to claim 5,wherein the second dihedral angle is smaller than the first dihedralangle.
 8. The optical assembly according to claim 2, wherein each of theplurality of microstructures is a prism.
 9. The optical assemblyaccording to claim 2, wherein the weight ratio of the photo-curableportion of the adhesive to the thermally-curable portion of the adhesiveis configured such that the adhesive force between the adhesive and theplurality of microstructures of the second optical film is larger than100 g/25 mm and the optical gain of the optical assembly is larger than1.6.
 10. The optical assembly according to claim 9, wherein thethickness of the adhesive is 0.5˜3 μm.
 11. The optical assemblyaccording to claim 1, wherein the weight ratio of the photo-curableportion of the adhesive to the thermally-curable portion of the adhesiveis 0.11˜4.
 12. The optical assembly according to claim 1, wherein theweight ratio of the photo-curable portion of the adhesive to thethermally-curable portion of the adhesive is 0.3˜1.08.
 13. The opticalassembly according to claim 2, wherein the weight ratio of thephoto-curable portion of the adhesive to the thermally-curable portionof the adhesive is 0.11˜4 such that the adhesive force between theadhesive and the plurality of microstructures of the second optical filmis larger than 100 g/25 mm and the optical gain of the optical assemblyis larger than 1.6.
 14. The optical assembly according to claim 13,wherein the thickness of the adhesive is 0.5˜3 μm.
 15. The opticalassembly according to claim 2, wherein the weight ratio of thephoto-curable portion of the adhesive to the thermally-curable portionof the adhesive is 0.25˜2.33 such that the adhesive force between theadhesive and the plurality of microstructures of the second optical filmis larger than 100 g/25 mm and the optical gain of the optical assemblyis larger than 1.6.
 16. The optical assembly according to claim 15,wherein the thickness of the adhesive is 0.5˜3 μm.
 17. The opticalassembly according to claim 1, wherein the photo-curable portion of theadhesive and the thermally-curable portion of the adhesive respectivelyoriginate from a first material and a second material different thefirst material.
 18. The optical assembly according to claim 1, whereinthe photo-curable portion of the adhesive and the thermally-curableportion of the adhesive originate from a single material.
 19. An opticalassembly, comprising: a first optical film having a first surface; anadhesive disposed on the first surface of the first optical film,wherein the adhesive comprises a thermally-curable portion and aphoto-curable portion; and a second optical film comprising athermally-curable material bonded to the thermally-curable portion ofthe adhesive, wherein the thermally-curable portion of the adhesive isbeing bonded to the thermally-curable material of the second opticalfilm when the thermally-curable portion of the adhesive is being curedand the photo-curable portion of the adhesive has been cured.
 20. Anoptical assembly, comprising: a first optical film having a firstsurface; an adhesive disposed on the first surface of the first opticalfilm, wherein the adhesive comprises a first curable portion and asecond curable portion; and a second optical film comprising a curablematerial bonded to the second curable portion of the adhesive, whereinthe first curable portion of the adhesive is cured by a first process,and the second curable portion of the adhesive and the curable materialof the second optical film are cured by a second process different fromthe first process, wherein the second curable portion of the adhesive isbeing bonded to the curable material of the second optical film when thesecond curable portion of the adhesive is being cured and the firstcurable portion of the adhesive has been cured.